JP2008181185A - Numerical simulation result display program, numerical simulation result display method, and numerical simulation result display system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a numerical simulation result display program which is advantageous for shortening a time required for analysis and inspection. <P>SOLUTION: An operator simultaneously sees three-dimensional CAD model data Dc displayed on a display device 22 and numerical simulation result data Ds(physical quantity) in order to visually confirm the shape of the target object displayed by the three-dimensional CAD model data Dc and the numerical simulation result data Ds (physical quantity) simulation result in association with each other. Thus, the numerical simulation result display program is advantageous for shortening the time required for analysis and inspection. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a numerical simulation result display program, a numerical simulation result display method, and a numerical simulation result display system.

Currently, numerical simulation technology using numerical analysis methods such as difference method, finite element method, finite volume method, boundary element method has been developed in a wide range of fields such as structural analysis, heat transfer analysis, thermal fluid analysis, electromagnetic field analysis, etc. Numerical simulation technology is being put into practical use as a means of elucidating the problem.
When performing such numerical simulation, dedicated analysis software (simulator) prepared according to the type of physical quantity to be analyzed is used, and the numerical simulation result is obtained by, for example, simplifying the color of a simplified model. It is displayed by methods such as adding shading or changing the color tone (see Patent Document 1).
Also, 3D CAD software is used in mechanism design and the like, and by using 3D CAD software, a 3D CAD model created by the 3D CAD software is displayed in 3D (Patent Literature). 2).
JP 2005-44146 A JP 2006-195971 A

By the way, as described above, each numerical simulation is performed by independent dedicated analysis software, and these multiple analysis softwares operate on different platforms, so it is not possible to operate them simultaneously on the same platform. Can not.
Therefore, it is impossible to simultaneously display and compare the results of numerical simulations of physical quantities of different types, for example, the results of structural analysis, thermal fluid analysis, and electromagnetic field analysis.
Therefore, a plurality of physical phenomena calculated by each numerical analysis cannot be confirmed at the same time. In order to examine a plurality of physical phenomena, it is necessary to switch analysis software each time.
Therefore, it is necessary to use a plurality of analysis software for the examination, and there is an inconvenience of requiring a lot of time for the analysis and examination because they cannot be viewed at the same time.
Naturally, the 3D CAD software also operates on a platform different from the above-described analysis software platform. Therefore, the 3D CAD software is generated by the 3D CAD software and each analysis software. It is also impossible to display the results of numerical simulations simultaneously on the same platform.
Therefore, the three-dimensional model and a plurality of physical phenomena calculated by each numerical analysis cannot be confirmed at the same time, and there is a disadvantage that much time is required for analysis and examination.
Further, the numerical simulation model performs calculation by subdividing elements from the model shape in the design. This subdivided element is used as one calculation unit (mesh) to perform numerical calculation.
If element subdivision is performed faithfully to the model shape in the design, the number of meshes becomes enormous. Therefore, the normal numerical analysis model is created by modifying the model shape in the design. Depending on the type of analysis (structural analysis, thermal fluid analysis, etc.), the model modification and shape are different.
Under such circumstances, even in the same analysis target model, there is a considerable difference in shape between the three-dimensional CAD model data generated by the three-dimensional CAD software and various numerical analysis model data.
When displaying the above-mentioned 3D CAD model data and various numerical analysis model data by switching the software, the consistency of the shape between the 3D CAD model and the numerical analysis model, or the numerical analysis models of different methods is set. It is difficult to take and requires a lot of time for analysis and examination.
The present invention has been devised in view of the above circumstances, and the object of the present invention is to simultaneously display three-dimensional model data and various numerical simulation result data when examining various numerical simulation results. An object of the present invention is to provide a numerical simulation result display program, a numerical simulation result display method, and a numerical simulation result display system that are advantageous in shortening the time required for analysis and examination.

In order to achieve the above-described object, the numerical simulation result display program of the present invention is input in a three-dimensional CAD model data input step for inputting three-dimensional CAD model data of an analysis object and the three-dimensional CAD model data input step. A CAD model data conversion step for converting the three-dimensional CAD model data into CAD graphic data that can be displayed on a display device; a numerical simulation result data input step for inputting numerical simulation result data of the analysis object; A simulation result converting step of converting the numerical simulation result data input in the simulation result data input step into simulation result graphic data which can be displayed on the display device; and the CAD Characterized in that to execute a display step of displaying on the display device by superposing the graphics data for graphics data and the simulation results to a computer.
The numerical simulation result display method of the present invention includes a three-dimensional CAD model data input step for inputting three-dimensional CAD model data of an object to be analyzed, and the three-dimensional CAD model data input in the three-dimensional CAD model data input step. CAD model data conversion step for converting CAD data into CAD graphic data that can be displayed on a display device, a numerical simulation result data input step for inputting numerical simulation result data of the analysis object, and a numerical simulation result data input step A simulation result converting step of converting the numerical simulation result data thus obtained into simulation result graphic data that can be displayed on the display device; the CAD graphic data; Superposing the graphics for Interview configuration results data; and a display step of displaying on the display device.
Further, the numerical simulation result display system of the present invention is a display device, 3D CAD model data input means for inputting 3D CAD model data of an analysis object, and the 3D input by the 3D CAD model data input means. CAD model data conversion means for converting dimensional CAD model data into CAD graphic data that can be displayed on the display device, numerical simulation result data input means for inputting numerical simulation result data of the analysis object, and the numerical simulation result Simulation result conversion means for converting the numerical simulation result data inputted by the data input means into simulation result graphic data that can be displayed on the display device; the CAD graphic data; Superposing the simulation results for graphics data, characterized in that it comprises a display means for displaying on said display device.

  According to the present invention, the operator can simultaneously display the 3D CAD model data and the numerical simulation result data (physical quantity) displayed on the image output device so as to be displayed by the 3D CAD model data. The shape of the target object to be analyzed and the numerical simulation result data (physical quantity) can be viewed in association with each other, which is advantageous in reducing the time required for analysis and examination.

(First embodiment)
Next, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a configuration diagram of a computer that executes a numerical simulation result display program according to the present embodiment.
As shown in FIG. 1, the computer 10 includes a CPU 12, a ROM 14, a RAM 16, a mouse 18, a keyboard 20, a display device 22, a hard disk device (HDD) 24, a CD-ROM drive device 26, a communication I / F 28, a printer 30, and the like. It is configured to include.
The ROM 14 is configured by a non-volatile memory and stores setting data and the like.
The RAM 16 constitutes a working area.
The mouse 18 is an input device operated by an operator.
The keyboard 20 is an input device operated by an operator.
The display device 22 constitutes an image output device that displays images and characters. In this embodiment, it is configured to be capable of color display.
The hard disk device 24 stores an OS, various application software, and data.
The hard disk device 24 is installed with the numerical simulation result display program of the present embodiment.
The CD-ROM drive device 26 reads and writes a disk-shaped recording medium such as a CD-ROM.
The communication I / F 28 is connected to a network such as a LAN or the Internet, and manages communication with the network.
The printer 30 constitutes an image output apparatus that prints out images and characters.
The CPU 12 is connected to the ROM 14, RAM 16, mouse 18, keyboard 20, display device 22, hard disk device (HDD) 24, CD-ROM drive device 26, communication I / F 28, printer 30, and printer 30 described above. It governs the control of.
Further, the CPU 12 executes the numerical simulation result display program of the present embodiment, whereby the numerical simulation result display method of the present embodiment is executed.
The computer 10 constitutes the numerical simulation result display system of the present embodiment.

FIG. 2 is a diagram showing three-dimensional CAD model data of the analysis object.
In the present embodiment, the analysis object 40 is a video camera.
The analysis object 40 has a case 42 that constitutes an exterior. A display panel 44 on which a captured image is displayed is provided on the right side of the case 42 so as to be openable and closable. A recording / reproducing unit 46 for recording and reproducing data on a disk-shaped recording medium is provided.
A lens barrel 48 is provided at the front of the case 42 to guide the subject image to an image sensor incorporated in the case 42.
As shown in FIG. 2, the three-dimensional CAD model data accurately displays the outer shape of the analysis object 40 that is the actual analysis target.

FIG. 3 is a diagram illustrating numerical simulation result data obtained by performing a thermal fluid analysis of the analysis target object 40, and FIG. 4 is a diagram illustrating numerical simulation result data obtained by performing a structural analysis of the analysis target object 40.
As shown in FIGS. 3 and 4, the numerical simulation result data is shown by simplifying (modifying) the outer shape of the analysis target object 40 that is the analysis target.
In the thermal fluid analysis shown in FIG. 3, the outer shape of the analysis object 40 is simplified (modified) using an orthogonal difference mesh.
As shown in FIG. 3, in the case of thermal fluid analysis, the temperature as a physical quantity is displayed by a color shade difference or a color tone difference (color change). In FIG. 3, the color density difference or color tone difference is displayed as a change in hatching pattern.
In the structural analysis shown in FIG. 4, the outer shape of the analysis object 40 is simplified (modified) using a finite element method mesh.
As shown in FIG. 4, in the case of structural analysis, a stress as a physical quantity is displayed by a color shade difference or a color tone difference. In FIG. 4, the color density difference or color tone difference is displayed as a change in hatching pattern.
In FIG. 3 and FIG. 4, the numerical value of the physical quantity is shown as four stages for simplification of the drawings, but the numerical value of the physical quantity is arbitrary as long as it is in a visible range.
As shown in FIG. 5, the numerical simulation result display program of this embodiment displays the three-dimensional CAD model data shown in FIG. 2 and the numerical simulation result data shown in FIG. In other words, it functions as a viewer that displays the three-dimensional CAD model data shown in FIG. 2 and the numerical simulation result data shown in FIG.

Next, a numerical simulation result display method using the numerical simulation result display program of the present embodiment will be described in detail.
FIG. 5 is a flowchart of the numerical simulation result display program of this embodiment.
When the numerical simulation result display program is executed by the CPU 12, the following processing is executed.
First, the 3D CAD model data Dc of the analysis object 40 (see FIG. 2), which is the analysis object, is read (reading of initial data) (step S10: 3D CAD model data input step).
The three-dimensional CAD model data Dc is generated by a conventionally known three-dimensional CAD software. The three-dimensional CAD model data Dc can be read, for example, by using the CD-ROM drive device 26 to read the three-dimensional CAD model data Dc (file) recorded on a disc-shaped recording medium such as a CD-ROM. May be read via the communication I / F 28.
The read three-dimensional CAD model data Dc is temporarily stored in the hard disk device 24, for example.
Next, the three-dimensional CAD model data Dc once stored in the hard disk device 24 is converted into CAD graphic data Dg1 that can be displayed on the display device 22 (step S12: CAD model data conversion step).
The converted CAD graphic data Dg1 is temporarily stored in the hard disk device 24, for example.
As such conversion processing of the three-dimensional CAD model data Dc into the CAD graphic data Dg1, various conversion processing used in conventionally known three-dimensional CAD software can be employed. In such conversion processing, for example, the CPU 12 develops the three-dimensional CAD model data Dc read from the hard disk device 24 on the RAM 16 and performs arithmetic processing.
In the present embodiment, step S12 corresponds to the first conversion step in the claims.
Then, the CAD graphic data Dg1 is displayed on the display device 22, and an initial screen is displayed (step S14).

Next, an analysis type of numerical simulation result data (analysis result data) Ds to be displayed superimposed on the three-dimensional CAD model data Dc is selected (step S16: analysis type selection step).
This selection operation is performed, for example, when a menu screen for selecting an analysis method is displayed on the display device 22 and the CPU 12 accepts the operation content when the operator operates the mouse 18 or the keyboard 20.
Examples of the analysis type include various conventionally known analysis methods such as structural analysis, thermal fluid analysis, and electromagnetic field analysis.

Next, the numerical simulation result data Ds of the analysis object 40, which is the analysis object, corresponding to the analysis type selected in step S16 is read (step S18: numerical simulation result data input step). More specifically, the data format of the numerical simulation result data Ds differs depending on the analysis type, and the CPU 12 reads the numerical simulation result data Ds according to the data format selected in step S16 (analysis type selection step). Do.
The numerical simulation result data Ds is generated by conventionally known numerical analysis software. As in the case of the three-dimensional CAD model data Dc, for example, the numerical simulation result data Ds (file) recorded on a disk-shaped recording medium such as a CD-ROM is read into the CD-ROM drive device. 26 may be used, or may be read from the network via the communication I / F 28.
The read numerical simulation result data Ds is temporarily stored in the hard disk device 24, for example.
The numerical simulation result data Ds includes one or more kinds of physical quantities. In addition to the physical quantity, the numerical simulation result data Ds includes contour data obtained by simplifying the outer shape of the analysis target 40.
For example, if the analysis method is structural analysis, the numerical simulation result data Ds includes a plurality of types of physical quantities such as stress, strain, and shear stress.
Alternatively, if the analysis method is thermal fluid analysis, the numerical simulation result data Ds includes a plurality of types of physical quantities such as temperature, flow velocity, and heat flux.
In many cases, since the numerical simulation result data Ds changes with time, the numerical simulation result data Ds is often composed of a plurality of files generated for each time.
Therefore, it is determined whether or not the numerical simulation result data Ds to be read is final (step S20). If it is not final (No in step S20, “N”), the process returns to step S18 to perform reading, and the numerical simulation result data Ds to be read. Is final (Yes in Step S20), the process proceeds to Step S22.

Next, it is selected whether or not to display the numerical simulation result data Ds of another type of analysis method by superimposing it with the three-dimensional CAD model data Dc (step S22).
For this selection operation, for example, an analysis method is selected, or a menu screen for instructing the end of the selection is displayed on the display device 22, and the CPU 12 is operated by the operator operating the mouse 18 or the keyboard 20. This is done by accepting the content.
If it is selected to display other numerical simulation result data Ds (Yes in Step S22), the process proceeds to Step S16, and if the end of selection is selected (No in Step S22, “N”). ") Move to step S24.

When the reading of the numerical simulation result data Ds is completed in this way, the type of analysis method of the numerical simulation result data Ds to be displayed superimposed on the three-dimensional CAD model data Dc is selected (step S24).
This selection operation is performed, for example, when a menu screen for selecting an analysis method is displayed on the display device 22 and the CPU 12 accepts the operation content when the operator operates the mouse 18 or the keyboard 20.
Next, the type of physical quantity of the numerical simulation result data Ds to be displayed superimposed on the three-dimensional CAD model data Dc is selected (step S26).
For example, if the analysis method selected in step S24 is structural analysis, the physical quantity of the numerical simulation result data Ds is selected from stress, strain, shear stress, etc., and the analysis method selected in step S24 is thermal fluid analysis. If there is, the physical quantity of the numerical simulation result data Ds is selected from temperature, flow velocity, heat flux, and the like.
This selection operation is performed, for example, when a menu screen for selecting a physical quantity is displayed on the display device 22 and the CPU 12 accepts the operation content when the operator operates the mouse 18 or the keyboard 20.

Then, the physical quantity of the numerical simulation result data Ds selected in step S26 is converted into simulation result graphic data Dg2 that can be displayed on the display device 22 (step S28: simulation result conversion step).
Various conversion processes used in conventionally known numerical simulation software can be adopted as the conversion process of the physical quantity of the numerical simulation result data Ds to the simulation result graphic data Dg2.
Further, the CAD graphic data Dg1 converted in step S12 and the simulation result graphic data Dg2 converted in step S28 are displayed in the same coordinate system when they are displayed on the display device 22 in a superimposed manner. Adjusted to be displayed.
Next, the CAD graphic data Dg1 converted in step S12 and the simulation result graphic data Dg2 converted in step S28 are superimposed and simultaneously displayed on the display device 22 (step S30: display step).
FIG. 6 is an explanatory diagram illustrating a display example in which the three-dimensional CAD model data Dc and the numerical simulation result data Ds are superimposed and displayed on the display device 22.
When the analysis method is thermal fluid analysis, the three-dimensional CAD model data Dc (CAD graphic data Dg1) shown in FIG. 2 and the numerical simulation result data Ds (graphic for simulation result) by the thermal fluid analysis shown in FIG. By displaying heat as a physical quantity as data Dg2) in an overlapping manner, a display as shown in FIG.
In the display example of FIG. 6, the three-dimensional CAD model data Dc of the analysis object 40 that is the analysis object, and the numerical simulation result data Ds shown in three dimensions by simplifying (modifying) the outer shape of the analysis object 40. And are superimposed on each other.
At this time, the three-dimensional CAD model data Dc may display only the outline of the analysis object 40 or may display the surface of the analysis object 40 through the surface.
In the present embodiment, the numerical simulation result display system is configured by the computer 10 as described above, and the computer 10 that executes step S10 (three-dimensional CAD model data input step) performs three-dimensional CAD model data input means. The CAD model data conversion means is configured by the computer 10 that executes step S12 (CAD model data conversion step), and the numerical simulation result data input step by the computer 10 that executes step S18 (numerical simulation result data input step). And a simulation result converting means is configured by the computer 10 executing step S28 (simulation result converting step) and executing step S30. Display means are constituted by Yuta 10.

Therefore, according to the present embodiment, the operator visually recognizes the three-dimensional CAD model data Dc and the numerical simulation result data Ds (physical quantity) displayed superimposed on the display device 22 so that the three-dimensional The shape of the analysis object displayed by the CAD model data Dc and the numerical simulation result data Ds (physical quantity) simulation result can be viewed in association with each other, which is advantageous in shortening the time required for analysis and examination. Become.
That is, in the present embodiment, it can be easily understood which part of the analysis object 40 (three-dimensional CAD model) the distribution based on the numerical simulation result data Ds (color difference or shade difference) corresponds to.

As a display form when the three-dimensional CAD model data Dc and the numerical simulation result data Ds are superimposed and displayed, the following display form is possible in addition to the display example shown in FIG.
As shown in FIG. 7, numerical simulation result data Ds in the cross section of the analysis object 40 corresponding to the cross-sectional view along the line AA in FIG. 3 is obtained.
Then, as shown in FIG. 8, the three-dimensional CAD model data Dc (CAD graphic data Dg1) shown in FIG. 2 and the numerical simulation result data Ds (simulation result graphic data Dg2) in the cross section shown in FIG. Overlay and display.
More specifically, in the display example of FIG. 8, the three-dimensional CAD model data Dc of the analysis object 40 that is the analysis object, and the numerical simulation result data Ds that shows the cross-sectional shape of the analysis object 40 in two dimensions Are superimposed and displayed.
Even in such a display form, the operator visually recognizes the three-dimensional CAD model data Dc and the numerical simulation result data Ds (physical quantity) at the same time, thereby displaying the analysis object displayed by the three-dimensional CAD model data Dc. And the numerical simulation result data Ds (physical quantity) in the cross section can be viewed in association with each other, which is advantageous in reducing the time required for analyzing and examining the analysis result.
That is, in the present embodiment, the numerical simulation result data Ds is displayed in such a manner that the physical quantity at the arbitrarily designated cross-sectional portion is displayed as a distribution based on the color tone difference or the light / dark difference. The physical quantity distribution in the model) can be grasped, and detailed examination is possible.
In this case, a cross-sectional shape position setting step for determining the position of the cross-sectional shape of the analysis object 40 according to the operation of the operator may be added.
That is, in the cross-sectional shape position setting step, after the initial screen is displayed in step S14, a setting screen for designating the position of the cross-sectional shape of the analysis object 40 is displayed, and the operator moves the mouse on the setting screen. By operating the 18 or the keyboard 20, the CPU 12 accepts the operation input and determines the position of the cross-sectional shape of the analysis object 40.

Further, a first display in which the three-dimensional CAD model data Dc and the numerical simulation result data Ds obtained by the first analysis method are superimposed on one screen of the display device 22, and the three-dimensional CAD model data Dc. The second display obtained by superimposing the numerical simulation result data Ds obtained by the second analysis method may be displayed simultaneously (aligned).
In this case, since the numerical simulation result data Ds (physical quantity) of different analysis methods can be viewed at the same time, in order to shorten the time required to simultaneously analyze and examine the analysis results of the different analysis methods. It will be advantageous.
In other words, numerical simulation results of different analysis methods on the same screen can be superimposed and displayed on the 3D CAD model at the same time, making it possible to perform a study without being aware of the difference in model shape between different analysis methods. .
Note that the types of different analysis methods to be displayed at the same time are not limited to two types as described above, and it is a matter of course that analysis results by three or more different analysis methods may be displayed side by side at the same time.

In the display step of step S30, a first display state in which the three-dimensional CAD model data Dc and the numerical simulation result data Ds by the first analysis method are superimposed on one screen of the display device 22, The second display state in which the three-dimensional CAD model data Dc and the numerical simulation result data Ds obtained by the second analysis method are superimposed is displayed according to the operation input of the operator (operation input of the mouse 18 and the keyboard 20). The CPU 12 may be switched and displayed.
In this case, since the numerical simulation result data Ds (physical quantity) of different analysis methods can be switched and viewed, the time required for analyzing and examining the analysis results of the different analysis methods can be reduced. It is advantageous in planning.
That is, by instantaneously switching the numerical simulation result display, it becomes possible to study from various aspects based on various physical phenomena.
Note that the types of different analysis methods to be switched and displayed are not limited to two as described above, and it is a matter of course that analysis results by three or more different analysis methods may be switched and displayed. .

In the present embodiment, the case where the physical quantity of the numerical simulation result data Ds is displayed with a color tone difference and a light and shade difference has been described, but the display form of the physical quantity of the numerical simulation result data Ds is not limited to these. The following may be displayed.
The physical quantity of the numerical simulation result data Ds may be displayed by replacing it with at least one of the direction of the arrow, the length of the arrow, the width of the arrow, and the color of the arrow. In this case, it is suitable for displaying a physical quantity including a direction such as a pulling direction and a compression direction like a main stress in a structural analysis, or a physical quantity including a direction like a flow velocity of heat in a thermal fluid analysis.
Further, the physical quantity of the numerical simulation result data Ds may be displayed by contour lines connecting the coordinates of the physical quantities having the same numerical value.
Further, the physical quantity of the numerical simulation result data Ds may be displayed by hatching direction and density, dot density, or pattern change.
In this embodiment, the case where the analysis method is structural analysis or thermal fluid analysis has been described. However, the analysis method is not limited to these, and various conventionally known analysis methods such as heat transfer analysis and electromagnetic field analysis can be used. Of course, the method can be used.
In the present embodiment, the case where the display device 22 is used as the image output device has been described. However, it goes without saying that the printer device 30 may be used instead of the display device 22.

It is a block diagram of the computer which performs the numerical simulation result display program of this Embodiment. It is a figure which shows the three-dimensional CAD model data of an analysis target object. It is a figure which shows the numerical simulation result data which performed the thermofluid analysis of the analysis target object. It is a figure which shows the numerical simulation result data which performed the structural analysis of the analysis target object. It is a flowchart of the numerical simulation result display program of this Embodiment. It is explanatory drawing which shows the example of a display on which the three-dimensional CAD model data Dc and the numerical simulation result data Ds were superimposed, and were displayed on the display apparatus 22. FIG. It is explanatory drawing of the numerical simulation result data Ds in a cross section. It is explanatory drawing which shows the example of a display on which the three-dimensional CAD model data Dc and the numerical simulation result data Ds in a cross section were superimposed, and were displayed on the display apparatus 22. FIG.

Explanation of symbols

  10: Computer, 22: Display device, 40: Analysis object, Dc: Three-dimensional CAD model data, Ds: Numerical simulation result data.

Claims (13)

A three-dimensional CAD model data input step for inputting the three-dimensional CAD model data of the analysis object;
A CAD model data conversion step of converting the three-dimensional CAD model data input in the three-dimensional CAD model data input step into CAD graphic data that can be displayed on an image output device;
Numerical simulation result data input step for inputting numerical simulation result data of the analysis object;
A simulation result conversion step of converting the numerical simulation result data input in the numerical simulation result data input step into graphic data for simulation results that can be displayed on the image output device;
A display step of superimposing the CAD graphic data and the simulation result graphic data on the image output device; and
Numerical simulation result display program for causing computer to execute The numerical simulation result data includes one or more physical quantities,
In the display step, the physical quantity is replaced with a color tone difference or a shade difference and displayed.
The numerical simulation result display program according to claim 1, wherein: The numerical simulation result data includes one or more physical quantities,
In the display step, the physical quantity is displayed by being replaced with at least one of an arrow direction, an arrow length, an arrow width, and an arrow color.
The numerical simulation result display program according to claim 1, wherein: The numerical simulation result data includes one or more physical quantities,
In the display step, the physical quantity is displayed by a contour line connecting coordinates of physical quantities having the same numerical value.
The numerical simulation result display program according to claim 1, wherein: The display step displays the physical quantity corresponding to the three-dimensional shape of the analysis object.
The numerical simulation result display program according to claim 1, wherein: The display step displays the physical quantity corresponding to a cross-sectional shape of the analysis object;
The numerical simulation result display program according to claim 1, wherein: The display step displays the physical quantity corresponding to the cross-sectional shape of the analysis object,
The display step includes a cross-sectional shape position setting step for determining a position of the cross-sectional shape in the analysis object according to an operation of an operator.
The numerical simulation result display program according to claim 1, wherein: The numerical simulation result data input step inputs the numerical simulation result data corresponding to one kind of analysis method.
The numerical simulation result display program according to claim 1, wherein: The numerical simulation result data input step inputs first and second numerical simulation result data corresponding to the first and second analysis methods,
The simulation result conversion step converts the first and second numerical simulation result data input in the numerical simulation result data input step into first and second simulation result graphic data that can be displayed on the image output device. Converted,
In the display step, the CAD graphic data and the first simulation result graphic data are superimposed and displayed on the image output device, and at the same time, the CAD graphic data and the second simulation result graphic data are displayed. Are displayed on the image output device in a superimposed manner.
The numerical simulation result display program according to claim 1, wherein: The numerical simulation result data input step inputs first and second numerical simulation result data corresponding to the first and second analysis methods,
The simulation result conversion step converts the first and second numerical simulation result data input in the numerical simulation result data input step into first and second simulation result graphic data that can be displayed on the image output device. Converted,
The display step includes a first display state in which the CAD graphic data and the first simulation result graphic data are superimposed and displayed on the image output device, the CAD graphic data and the second simulation. Switching the second display state to be displayed on the image output device by superimposing the result graphic data on the basis of an operation input by the operator;
The numerical simulation result display program according to claim 1, wherein: The image output device is a display device or a printer device.
The numerical simulation result display program according to claim 1, wherein: A three-dimensional CAD model data input step for inputting the three-dimensional CAD model data of the analysis object;
A CAD model data conversion step of converting the three-dimensional CAD model data input in the three-dimensional CAD model data input step into CAD graphic data that can be displayed on an image output device;
Numerical simulation result data input step for inputting numerical simulation result data of the analysis object;
A simulation result conversion step of converting the numerical simulation result data input in the numerical simulation result data input step into graphic data for simulation results that can be displayed on the image output device;
A display step of superimposing the CAD graphic data and the simulation result graphic data on the image output device; and
A numerical simulation result display method characterized by comprising: An image output device;
3D CAD model data input means for inputting 3D CAD model data of an analysis object;
CAD model data conversion means for converting the three-dimensional CAD model data input by the three-dimensional CAD model data input means into CAD graphic data that can be displayed on the image output device;
Numerical simulation result data input means for inputting numerical simulation result data of the analysis object;
Simulation result conversion means for converting the numerical simulation result data input by the numerical simulation result data input means into graphic data for simulation results that can be displayed on the image output device;
Display means for superimposing the CAD graphic data and the simulation result graphic data on the image output device;
A numerical simulation result display system comprising:

Images